Kidde Fire Protection SIRIUS User manual
TM0066 Page 1 of 39 Issue 2.01
SIRIUS
MANUAL
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TM0066 Page 2 of 39 Issue 2.01
PROPRIETARY RIGHTS NOTICE
The information contained in this manual is the property of Kidde Fire Protection Services Limited and
may not be reproduced or transmitted in any form or by any means, electronic, mechanical,
photocopying, recording or otherwise, nor stored in any retrieval system of any nature without the
express written authority of Kidde Fire Protection Services Limited.
© Copyright 2002 Kidde Fire Protection Services LTD
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Preliminary Pages
AMENDMENT INCORPORATION RECORD
Amendment
Number Brief Description of Content Name of Person
Incorporating
Amendment
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Preliminary Pages
AMENDMENT INCORPORATION RECORD
Amendment
Number Brief Description of Content Name of Person
Incorporating
Amendment
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Preliminary Pages
TABLE OF CONTENTS
Chapter Page
1 GENERAL SPECIFICATION 9
1.1 INTRODUCTION 9
1.2 MECHANICAL CONSTRUCTION 9
1.2.1 General Details 9
1.2.2 Panel Specification 10
1.3 FUNCTIONAL DESCRIPTION 10
1.3.1 Panel Indications 11
1.3.2 Panel Control Switches 11
1.3.3 Internal Indications and Control 11
1.4 COMPATIBILITY 12
1.4.1 Automatic Devices 13
1.4.2 Manual Devices 14
2 INSTALLATION AND COMMISSIONING 15
2.1 GENERAL 15
2.1.1 Static Sensitive Devices 15
2.2 INSTALLATION 16
2.3 COMMISSIONING 16
2.3.1 Supply Checks 17
2.3.2 Zonal Checks 18
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Preliminary Pages
TABLE OF CONTENTS
Chapter Page
2.3.3 Fault Conditions 18
2.3.4 Sounder Circuit Check 18
3 PERFORMANCE SPECIFICAITON 21
3.1 ALARM CONDITION 21
3.2 FAULT CONDITION 21
3.3 DISABLEMENT 22
3.4 TEST MODE 22
3.5 RELAY ISOLATE 23
3.6 DEFINITIONS 23
4 MAINTENANCE 25
4.1 GENERAL 25
4.2 ROUTINE MAINTENANCE 25
4.3 ENGINEERS CONTROLS 26
5 TECHNICAL SPECIFICATIONS 27
5.1 2 ZONE PANEL 27
5.2 4 ZONE PANEL 29
5.3 8 ZONE PANEL 31
5.4 16 ZONE PANEL 33
5.5 32 ZONE PANEL 36
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Preliminary Pages
TABLE OF CONTENTS
Chapter Page
6 VOLTAGE AND CURRENT CALCULATIONS 37
6.1 2 ZONE PANEL 37
6.2 4 ZONE PANEL 38
6.3 8 ZONE PANEL 38
6.4 16 ZONE PANEL 39
6.5 32 ZONE PANEL 39
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CHAPTER 1
GENERAL SPECIFICATION
1.1 INTRODUCTION
This range of self contained control panels provides conventional detection ranging from 2 to 32
zones and are available with LPC approval to BS 5839 Part 4 1988.
1.2 MECHANICAL CONSTRUCTION
1.2.1 General Details
The enclosures are constructed of 1.6 mm (16 swg) mild steel and have a paint finish of ash grey,
semi gloss BS OOAO1 which is powder coated prior to baking. The enclosures are designed to
afford a degree of protection to IP 52 to BS/EN 60529 when the outer door is closed. Each
enclosure consists of 4 main components.
Back Box
Inner Mounting chassis
Glazed lockable door
Battery securing brackets
1.2.1.1 Back Box
The back box is constructed of a single sheet of mild steel with the minimum of welds. Cable
entry is via pre-formed 20 mm knockouts located in the top of the enclosure. The back of the
case is provided with a keyhole locating hole for positioning of the back box and can then be
secured by utilizing the four 4 mm indented holes located near each corner.
1.2.1.2 Glazed Lockable Door
The door is connected to the back box by a piano type hinge on the left-hand side of the
enclosure. The door can be opened through 170 degrees to enable access to the panels operating
and display membrane. The door is secured by means of an 827 cam lock and is served with a
logo plate which is located in the bottom right hand corner of the door. The viewing window is
constructed of 3 mm acrylic perspex. The door is removable by means of 4 nuts and studs.
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1.2.1.3 Inner Mounting Chassis
The chassis is mounted on the back box by means of five M4 x 6 mm screws which are
accessible without removing the mother board. The chassis is served with a piano type hinge on
the right hand side which allows the membrane to be opened through 90 degrees and the
membrane is secured by means of three "Allen" type bolts located on the left hand side of the
membrane.
1.2.1.4 Battery Brackets
Battery space has been allocated at the bottom of the back box and this has been designed around
the Yuasa range of sealed lead acid cells. The batteries are clamped into position by means of
two brackets which are secured at each end of the brackets by two M4 x 6 mm screws.
1.2.2 Panel Specific Details
No of
Zones Ref No. Dimensions Knock
Outs Weight include
batteries (kg) Battery
size(Ah)
2 SR2000 276(h) x 306(w) x 100(d) 10 9 2 x 3.2
2 SR2001 370(h) x 330(w) x 113(d) 14 11 2 x 6
4 SR4000 276(h) x 306(w) x 100(d) 10 9 2 x 3.2
4 SR4001 370(h) x 330(w) x 113(d) 14 11 2 x 6
8 SR8000 370(h) x 330(w) x 113 (d) 14 16 2 x 6
16 SR1600 450(h) x 440(w) x 138(d) 22 20 2 x 12
32 SR3200 450(h) x 880(w) x 138(d) 44 40 2 x 12
Plain case enclosures are available in all sizes to accommodate additional equipment which can
be mounted on a purpose made, detachable mounting plate.
1.3 FUNCTIONAL DESCRIPTION
The membrane display is constructed of a smooth anti-static, polycarbonate material which
incorporates tactile switches and LED indications.
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1.3.1 Panel Indications
Twin Fire LEDs (Red)
Supply Healthy LED (Green)
System Fault LED (Amber)
Disablement LED (Amber)
Test LED (Amber)
User LED # 1 (Amber)
User LED # 2 (Amber)
Zonal Alarm LEDs (1 Per Zone) (Red)
Zonal Fault LEDs (1 Per Zone) (Amber)
Processor Fault LED (Amber)
1.3.2 Panel Control Switches
Sounds Alarms
Silence Alarms
Systems Reset
Relay Isolate
Keypad - Digits 0 to 9
Cancel (Also clears the processor fault indication, 2 and 4 zone
panels only)
Enter
1.3.3 Internal Indications and Controls
Secured to the chassis is the motherboard which incorporates controls and indications for
engineering purposes.
1.3.3.1 Indications
LED1 - Power Supply Fault LED (Amber)
LED2 - Alarm Circuit Fault LED (Amber)
LED3 - Membrane Disconnection LED (Amber)
LED 4 - Earth Fault LED (Amber)
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1.3.3.2 Controls
4-way dil switch SW1
Leaf 1 OFF Sounder circuit constant
Leaf 1 ON Sounder circuit pulsed
Leaf 2 ON Zone 1 non latching mode (disallowed
under BS 5839 Part 4 1988)
Leaf 3 ON Inititate panel test mode
Leaf 4 ON Operates the processor fault counter
reset on the 8, 16 and 32 zone panels
only.
Voltage regulator VR1 Adjustment of the charging voltage.
1.4 COMPATIBILITY
The range of control panels have been approved to operate with the following range of devices:
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1.4.1 Automatic Devices
Manuf. Part No. Base No. Device Type
Apollo 53541-151
53551-201
53531-221
55000-300
55000-200
55000-210
55000-100
45681-007
45681-007
45681-007
45681-200
45681-200
45681-200
45681-200
Ionisation smoke detector
Photo-electric smoke detector
Grade 1 rate of rise heat detector
Photo-electric smoke detector
Ionisation smoke detector
Integrated Ionisation smoke detector
Grade 1 heat detector
Hochiki SLK-E
DFE-60
DFE-90
DCA-E60B
DCC-1EL
DCC-2EL
DCC-R1EL
YBF-RL\4H5
YBF-RL\4H5
YBF-RL\4H5
YBF-RL\4H5
YBF-RL\4H5
YBF-RL\4H5
YBF-RL\4H5
Photo-electric smoke detector
Heat detector
Heat detector
Rate of rise heat detector
Grade 1 rate of rise heat detector
Grade 2 rate of rise heat detector
Range 1 rate of rise heat detector
Nittan NID-58
2KC
TCA-70-LS
NHD-G1(4T)
NHD-G2 (4T)
NHD-G3 (4T)
NHD-
GH1(4T)
2KH-4T
2IC-4T
RB-3R
RB-3R
RB-3R
RB-3R
RB-3R
RB-3R
RB-3R
RB-3R
RB-3R
Ionisation smoke detector
Photo-electric smoke detector
Heat detector
Grade 1 fixed temperature heat detector
Grade 1 fixed temperature heat detector
Grade 1 fixed temperature heat detector
Range 1 fixed temperature heat detector
Photo-electric smoke detector
Ionisation smoke detector
Kidde
Fenwall CPD7051
PSD715X 70-501000-001
70-501000-001 Ionisation smoke detector
Photo-electric smoke detector
Photain ISD-P91
PRR-P91
PHD-P90
FSB-P91
FSB-P91
FSB-P91
Ionisation smoke detector
Grade 1 rate of rise heat detector
Range 1 heat detector
NOTEWhen using Nittan NID58, 2KC or TCA-70-LS devices ensure that the following
instructions are followed:-
RB-3 bases used: Ensure that Part No. CPR2 type bases are used.
RB-6 bases used: Ensure that a 220 ohms resistor is fitted across terminals L and S1.
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1.4.2 Manual Devices
MANUFACTURER PART NO. DESCRIPTION
KAC KR9/510 Call point complete with
resistor
KAC KR72 Call point
FKI MCP/R/F Call point
NOTES 1. All break glass call points must have a 510 ohm resistor in series with
the normally open alarm contacts.
2. The quiescent current of a detection zone without an end-of-line
resistor fitted is 2.6mA.
3. The maximum line resistance of a detection zone is 50 ohms.
4. The end-of-line resistor value for detection zones is 3K9 ohms. ¼
watt.
5. The end of line resistor valve for alarm circuits is 2k2 Ohms ½ watt.
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CHAPTER 2
INSTALLATION AND COMMISSIONING
2.1 GENERAL
The installation of the fire detection and alarm system should comply with the current editions
of:-
1. The IEE Wiring Regulations.
2. The British Standard for Fire Detection and Alarm Systems for Buildings.
Care should be taken not to install cables in the proximity of high voltage cables or in areas likely
to induce electrical interference.
Junction boxes should be avoided but if they have to be installed then they must clearly be
labelled "Fire Alarm".
2.1.1 Static Sensitive Devices
A static sensitive device is any transistor or integrated circuit which may be permanently
damaged due to electrostatic potentials and is generally encountered during routine handling,
repair and transportation.
Static electricity is produced almost every time plastics or textiles are stroked or separated.
Static charges are collected on adjacent conductors and are delivered in the form of sparks
passing between conductors through insulating space or material. The sweat layer on the human
skin is a sufficient medium to store induced static charges and deliver then to any receptive
conductor such as a component or printed circuit board.
Static discharges can be reduced by adhering to the following guide lines:
1. Always use conductive or anti-static containers for transportation of storage.
2. Wear an earth wrist strap while handling, ensuring a good earth connection is maintained.
3. Never subject a static sensitive device to a sliding movement over any surface and avoid
any direct contact with the pins.
4. Avoid placing sensitive devices on plastic or vinyl surfaces.
5. Minimize the handling of sensitive devices and pcb's.
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All static sensitive devices are marked accordingly, but it is good engineering practice to treat
all components and boards with the same degree of protection.
2.2 INSTALLATION
Remove the inner chassis which incorporates the motherboard and the membrane by unscrewing
the five securing screws, which should be replaced in their original nut inserts for safe keeping.
Ensure that the chassis is stored in a safe environment in accordance with the precautions detailed
in Section 2.1.
The keyhole location provides a provisional means of fixing the back box to it's desired location
which allows alignment and final fixing is accomplished by utilizing the four indented holes.
Ensure that the enclosure and the glazed door are given protection during the installation period.
All external cables are to be glanded via the 20 mm pre-formed knockouts located on the top of
the enclosure. When the installation of all cables has been completed, clean the interior of the
enclosure ensuring that all masonry debris and drilling swarf are removed.
2.3 COMMISSIONING
Check that all external wiring is correctly identified and using a multimeter check that the cables
are free from fault conditions (earth, short- and open-circuit).
Re-install the inner chassis into the backbox and connect the external wiring into their respective
terminals replacing any end-of-line resistors to the last device on the circuit.
Prior to connecting the mains supply use a multimeter to ensure that the supply is not present and
take precautionary steps to avoid accidental application of the supply. Connect the supplycables
into the mains input terminals and remove the local on-board mains fuse.
Prior to the initial power up of the panel conduct a series of preliminary checks:-
- Check for any visible signs of damage which may have been caused during the
installation.
- Verify that all installation instructions have been adhered to.
- Physically check that the main pcb is secure in it's mounting.
- Check that the ribbon cable is secure and correctly connected.
- Check that all cable terminations are secured.
All damage/faults must be rectified before proceeding.
Apply the mains supplyfrom the remote source, using a multimeter check that the supply voltage
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is present at the on-board mains terminal and insert the mains fuse, check that the panel performs
the following functions:
1. The supply healthy LED illuminates
2. The system fault LED illuminates
3. The internal buzzer pulses
4. The fault relay operates
No other fault indications should be present at this stage and if faults exist, clear before
continuing. At this stage the batteries are not to be connected leaving the resistor to hold off the
fault condition.
Place the multimeter probes across the battery terminals (with the resistor still in place) and set
the output voltage to 27.5 volts d.c. by adjusting VR1.
Operate the reset button and check that all LED's illuminate and the internal buzzer operates.
Operate the sound alarms button and check that the sounder circuits operate in a continuous mode
and when the silence alarm button is pressed that the sounder circuits de-activate.
2.3.1 Supply Checks
Prior to the installation of the batteries the following procedures must be followed:
1. Check batteries for transit damage.
2. Check battery open circuit terminal voltage.
3. Record the installation date.
Remove the resistor from the battery terminals and observe that the supply healthy LED
extinguishes, the system fault LED illuminates, the internal buzzer operates in a pulsed mode.
Connect the batteries ensuring the correct polarity of the supply is maintained, press the reset
switch and check that the panel reverts to the normal condition, supply healthy LED illuminated.
The batteries should be allowed to charge for a full 24 hours prior to load tests being performed.
Check that the following supply fault conditions extinguish the supply healthy LED, illuminate
the system fault LED and operate the internal buzzer in a pulsed mode:-
1. Open circuit of the battery supply.
2. Removal of the mains fuse
3. Removal of FS2 on the motherboard.
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The panel must be reset after each fault condition.
2.3.2 Zonal Checks
For each detection zone the following procedures must be followed:-
2.3.3 Fault Conditions
Remove one leg of the external wiring (or end-of-line resistor) and check that the correct zonal
fault LED (amber) flashes in sympathy with the system fault LED and the internal buzzer.
Operate the silence alarms button and check that the internal buzzer reverts to an intermittent
mode. Replace the wiring (or end-of-line resistor), the panel will automatically reset and check
that the panel reverts to the normal operation condition, supply healthy LED illuminated.
Apply a short-circuit condition to the external wiring (or end-of-line resistor) and check that the
correct zonal fault LED (amber) flashes in sympathy with the system fault led and the internal
buzzer. Operate the silence alarms button and check that the internal buzzer reverts to an
intermittent mode. Remove the short circuit; the panel will automatically reset and check that
the panel reverts to the normal operating condition, supply healthy LED illuminated.
Using a 510 ohm resistor apply an alarm condition to the zonal terminals, check that the correct
zonal alarm LED (red), the twin fire LED's illuminate in a pulsed mode and that the internal
buzzer operates in a constant mode. Check that the sounder circuits operate in a constant mode
and that when the silence alarms button is operated that the sounders de-activate, the alarm zonal
LED and the twin fire LED's operate in a constant mode. The internal buzzer should revert to
the pulsed mode of operation. Press the reset button and check that the panel reverts to the
normal operating condition, supply healthy LED illuminated.
All detection devices connected to the control panel must be tested for correct operation and zone
designation.
Any earth faults will cause LED 4 to illuminate internally on the control board and the common
fault LED to illuminate on the display board.
2.3.4 Sounder Circuit Checks
For each sounder circuit the following procedures must be followed:
Apply a short-circuit condition to a sounder circuit and ensure that the external fault LED
illuminates and the internal buzzer operates in an intermittent mode. Check that the alarm fault
LED on the motherboard also illuminates in a constant mode. Clear the fault condition and press
the reset button check that the panel reverts to the normal operating condition, supply healthy
LED illuminated.
Apply an open-circuit condition to a sounder circuit and ensure that the external fault LED
illuminates and the internal buzzer operates in an intermittent mode. Check that the alarm fault
LED on the motherboard also illuminates in a constant mode. Clear the fault condition and press
TM0066 Page 19 of 39 Issue 2.01
the reset button check that the panel reverts to the operating condition, with the supply healthy
LED illuminated.
The audibility level of the sounders should be checked to ensure that they conform to BS 5839
Part 1, Section 2 clause 9.4.
NOTEUpon completion of commissioning of the system it is advisable to perform a
processor failure count check as described in the Engineers Controls section
of this manual. When a check has been performed, reset the counter to zero,
(8, 16 and 32 zone control panels only).
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